DE3505306C2 - - Google Patents

Description

The invention relates to an automatic Exposure control device for a photographic Camera with a mode setting device for setting different exposure control modes for the Automatic exposure mode of the photographic camera as well as with a digital counting device having digital evaluation circuit and with a Lens aperture ring on the camera lens, which one Has automatic position and manual position.

From DE-OS 29 04 818 is one Automatic exposure control device for one known photographic camera in which a variety of Exposure modes using a selector is adjustable. A first mode setting device is connected to a ring counter, the corresponding one Provides output signals whose digital combination as Coding combination is processed further. Besides, is a selector switch is provided which is an oscillator releases to generate clock signals corresponding to the clock input of the ring counter. With the help of this Selector switches are different modes, such as. B. Shutter priority aperture automatic mode, Aperture priority shutter automatic mode, Lock priority adjustment program mode,  Iris priority adjustment program mode and two Area program modes, adjustable. Furthermore is one Switch arrangement provided by the Aperture ring of the lens is actuated. The lens hood ring is in its Automatic position, so the ring counter mentioned with Using the switch devices set accordingly will. The lens hood ring is in one manual position, the aforementioned automatic Exposure modes locked. This means that in a such a manual position of the lens hood ring none automatic exposure modes are adjustable.

The invention is based on the object automatic exposure control device of the beginning to create the type mentioned, depending on the Automatic or manual position of the lens hood ring safe and easy selection and control of modes is possible within two mode ranges, of which the a mode area is a purely automatic mode area.

The task is characterized by the characterizing part of claim 1 included features solved.

Advantageously, the mode A counter looks as well the mode M counter one Aperture priority automatic exposure mode. Out of this there is also the advantage that also at accidental adjustment of the lens aperture ring in a manual position Aperture priority automatic exposure mode is possible. This means that in manual operation the assigned Mode M counter for manual modes in addition to the manual ones Modes also include an automatic exposure mode allowed. Furthermore, it is advantageous that with the help  of the lens hood ring two separate Exposure mode areas via the two mode counters are adjustable, whereby in Automatic exposure setting mode manual operating modes excluded are.

Further advantageous configurations can be found in the Subclaims.

The invention is described below with reference to exemplary embodiments shown in FIGS. 1 to 5. Show it

FIGS. 1A and 1B are perspective views of the positions of the push button switch and a locking pin for the automatic mode in a camera according to a preferred embodiment of the invention,

Fig. 2 is a block diagram which is used in a camera according to the invention of an electric circuit,

Fig. 3 is a schematic circuit diagram showing a mode-A-counter and a TV-counter and its associated circuitry in detail,

Fig. 4 is a schematic representation for displaying the modes and data for the output bits of the mode A counter, a mode M counter, the TV counter and an AV counter, and

Fig. 5 is a schematic circuit with a decoder and a memory which is used for displaying the output signals of the TV counter with the aid of LEDs.

FIGS. 1A and 1B according to the invention, are for schematically illustrating the positions of a push button switch, a display unit and locking pin for automatic operation in an automatic exposure camera.

In particular, FIG. 1A shows a connecting portion between the camera body and a lens. As shown in FIG. 1A, a locking pin 2 for the automatic operation on a lens aperture ring 1 is provided. When the lock pin 2 is locked, the automatic modes are enabled, and when it is not locked, the manual modes are enabled. A switch SW 1 ( Fig. 2) is actuated in connection with the locking pin 2 , so that data is transmitted from the switch SW 1 to a lens contact 3 . The data transmitted in this way are fed to a contact 3 a on the camera housing and processed as mode selection data.

Fig. 1B shows the top side of the camera body, on which the display unit 4, a Belichtungsfaktoreinstelltaste 5, a Filmempfindlichkeitseinstelltaste 6, a mode setting key 7, an upward selection key 8 and a down selection key 9 are arranged. The display unit provides the photographer with an indication of the automatic or manual mode (AUTO or M) as well as the exposure, the aperture value, the exposure factor and the film speed.

Fig. 2 contains a schematic electrical circuit for automatic exposure camera according to the invention.

Switches SW 1 , SW 2 , SW 3 , SW 4 , SW 5 and SW 6 are each provided for the locking pin 2 , for the mode setting button 7 , for the film sensitivity setting button 6 , for the exposure factor setting button 5 , for the up selection button 8 and for the down selection button 9 . The switch SW 1 is an automatic / manual switch for the selection of the automatic modes or the manual modes. It is operated in conjunction with the lens hood ring 1 . A mode A counter 21 is activated when the automatic / manual switch SW 1 selects the automatic modes. A mode M counter 22 becomes effective when the switch SW 1 selects the manual modes. The TV counter 25 contains values for the exposure time, while an AV counter 26 contains the aperture value. An SV counter 23 contains values for film sensitivity, and an EF counter 24 sets the exposure factor. The counters 21, 22, 25, 26, 23 and 24 described above are up-down counters. First connections of resistors R 1 , R 2 , R 3 , R 4 , R 5 and R 6 are each connected to first connections of switches SW 1 , SW 2 , SW 3 , SW 4 , SW 5 and SW 6, while the second Connections of these resistors are grounded. The second connections of the resistors R 1 to R 6 are connected to a voltage source. The connection point of the resistor R 1 and the switch SW 1 is connected to the input terminal of an inverter 11 and to an input terminal of an AND gate 12 . The connection point of the resistor R 2 and the switch SW 2 is connected to an input terminal of the mode A counter 21 , to an input terminal of the mode M counter 22 and to an input terminal of an inverter 13 . The output terminal of the inverter 13 is connected to one input terminal of an AND gate 14 and to the other input terminal of the AND gate 12 . The output terminal of the inverter 11 is connected to the other input terminal of the AND gate 14 , the output terminal of which is connected to the mode A counter 21 . The output terminal of the AND gate 12 is connected to the input terminal of the mode M counter 22 . The connection point of the resistor R 3 and the switch SW 3 is connected to the SV counter 23 via an inverter 15 . The connection point of the resistor R 4 and the switch SW 4 is connected to the EF counter 24 via an inverter 16 . The connection point of the resistor R 5 and the switch SW 5 is connected to the input terminal of an inverter 17 . The connection point of the resistor R 6 and the switch SW 6 is connected to the input terminal of an inverter 18 . The output terminals of the inverters 17 and 18 are connected to the mode A counter 21 , the mode M counter 22 , the SV counter 23 , the EF counter 24 , the TV counter 25 and the AV counter 26 . Output terminals of the mode A counter 21 are connected to the TV counter 25 and the AV counter 26, respectively. An output terminal of the mode M counter 22 is connected to the TV counter 25 , output terminals of the TV counter 25 , the AV counter 26 , the SV counter 23 and the EF counter 24 lead to a decoder 31 and a CPU 32 . In Fig. 2, a signal line, which is marked with a short oblique line, should clarify that it consists of a plurality of lines. The decoder 31 is connected to a display unit 34 via a driver 33 . The operation of the electrical circuit shown in FIG. 2 will now be described. First, the case is described in which the lens is in the automatic position. In this case the automatic / manual switch SW 1 is closed. An L signal is supplied to the AND gate 12 . At the same time, the inverter 11 supplies an output signal with an H level. The H signal is fed to the AND gate 14 . On the other hand, since the mode switch SW 2 , which is provided for the mode setting key 7 , is turned off, an H signal is supplied to the inverter 13 . Therefore, the output of the inverter 13 is set to low. Thus, the inputs of the AND gate 12 are at L. If the mode switch SW 2 is therefore in the OFF state, no chip selection signal CSM is output by the AND gate 12 and a chip selection signal CSA is output by the AND gate 14 . When the mode setting key 7 is pressed with the switch SW 1 closed, the switch SW 2 is turned on, so that the output signal of the inverter 13 is raised to H. Thus, the two inputs of the AND gate 14 are high and the chip select signal CSA is raised to high. The chip selection signal CSM of the AND gate 12 is at L because the AND input, which is connected to the switch SW 1 , has the potential L. When the chip select signal CSA is raised to high, the mode A counter 21 operates to receive a signal from the up switch SW 5 which is intended for the up select key 8 and a signal from the down switch SW 6 which is for the down select key 9 is provided. Assuming that a two-bit up-down counter is used as mode A counter 21 , four different modes can be set according to the logical counter output values of "00", "01", "10" and "11", using the signals of the up switch SW 5 and the down switch SW 6 . In the above-described embodiment, the modes are classified into an aperture priority automatic exposure mode, an exposure time priority automatic exposure mode and a program automatic exposure mode. One of these modes is selected. It is assumed that the aperture priority automatic exposure mode is selected by operating the up switch SW 5 or the down switch SW 6 . In this case, a chip select signal CSES is supplied to the signal line provided between the mode A counter 21 and the AV counter 26 , so that the latter is activated. Under this condition, when the mode switch SW 2 is turned off and the up switch SW 5 or the down switch SW 6 is pressed, the counting operation of the AV counter 26 selected by the chip select signal CSES is continued. In this up-counting operation, the content of the counter changes e.g. For example, as follows: Fl, 2 1.4 2 2.8 4 5.6 8 11 16 22 32 42 In the countdown operation, the content changes in reverse order. The case where the exposure time priority automatic exposure mode is selected will now be described. In this case, the mode setting switch SW 2 and the up switch SW 5 or the down switch SW 6 are operated to select a chip select signal CSEE of the mode A counter 21 to activate the TV counter 25 . Then, when the mode selection switch SW 2 is turned off again and the up switch SW 5 or the down switch SW 6 is pressed, the count value of the TV counter 25 is changed. By pressing the up switch SW 5 , the exposure time is changed in steps as follows: 1 1/2 1/4 1/8 1/15 1/30 1/60 1/125 1/250 1/500 1/1000 By pressing the down switch SW 6 the exposure time is reduced in reverse order. If the program automatic exposure mode is selected as a mode of the mode A counter 21 , the photographer cannot select an exposure time and an aperture value. Therefore, no chip select signal is given. In each of the two modes described above, the output signals of the counters are fed to the CPU 32 via two-bit bus lines, where they are subjected to the calculation and processed. The case where the lens is in the manual mode position will now be described. In this case the automatic / manual switch SW 1 is switched off. In contrast to the case where the lens is in the automatic position, when the switch SW 2 is turned on, the two inputs to the AND gate 12 are raised to H. Therefore, the chip select signal CSM is raised to high. One of the inputs to the AND gate 14 is raised to H while the other is set to L. Therefore, the chip select signal is CSA L. Since a two-bit up-down counter is used as the mode M counter 22 , four modes can be set according to the counter output values "00", "01", "10" and "11" by using the signals of the up switch SW 5 and the down switch SW 6 . In the embodiment described above, the four modes include the lamp mode, the flash sync exposure time mode, the manual exposure mode, and the aperture priority automatic exposure mode. Any of the four modes can be selected. Therefore, when the up switch SW 5 or the down switch SW 6 is turned on with the chip select signal CSM at H, the content of the mode M counter 22 can be changed. If e.g. B. the content of the mode M counter 22 is set to "01" by pressing or depressing the up switch SW 5 , the manual exposure mode is obtained. In this case, a chip select signal CS is supplied from the mode M counter 22 to the TV counter 25 . When the chip select signal CS is raised to H, the TV counter 25 is activated, thereby performing an up-count operation or a down-count operation depending on the operation of the up switch SW 5 or the down switch SW 6 . The operation of the TV counter 25 in this case is the same as the operation of the mode A counter described above when the automatic / manual switch SW 1 is turned on and the chip selection signal CSEE is high in the exposure time priority automatic exposure mode lies. When the output signal of the mode M counter 22 corresponds to the flash lamp mode, the electron flash synchronization mode or the aperture priority automatic exposure mode, the exposure time and the aperture value are not controlled by the up switch SW 5 and the down switch SW 6 . Therefore, no chip selection signal CS is generated. In each of these modes, two-bit data is transferred to the CPU 32 via the bus lines so that it is subjected to the calculation.

Now the film speed adjustment operation described.

When the SV switch SW 3 , which is operated in connection with the film sensitivity setting key 6 , is switched off, the output of the inverter 15 (chip selection signal CSSV) is at L. When the SV switch SW 3 is switched on, the chip selection signal is raised to H so that the SV counter 23 is activated. Under this condition, if the up switch SW 5 or the down switch SW 6 are turned on, the content of the SV counter can be changed. The SV data which has been set or set by the SV counter 23 are supplied via the bus line to the CPU 32 and are subjected to the operations in the desired manner. The exposure factor setting operation will now be described. If the EP switch SW 4 , which is provided for the exposure factor setting key 5 , is switched off, the output of the inverter 16 (chip selection signal CSEF) is at L. If the EF switch SW 4 is switched on under this condition, the input of the Inverters 16 set or set to L. Therefore, the chip select signal CSEF is raised to high. Under this condition, when the up switch SW 5 or the down switch SW 6 is turned on, the content of the EF counter 24 can be changed. The count data output signals of the TV counter 25 , the AV counter 26 , the SV counter 23 and the EF counter 24 are transmitted to the CPU 32 and the decoder 31 via the bus lines. The data of each counter is converted into display data by the decoder. The display data thus obtained are fed via the driver 33 to the display unit 34 , where they are displayed. Figure 3 shows mode A counter 21 , TV counter 25 , AV counter 26 and part of their peripheral circuitry. The output terminal of the inverter 17 is connected to an input terminal of an AND gate 41 , while the output terminal of the inverter 18 is connected to an input terminal of an AND gate 42 . A chip select signal CSA is supplied to the other input terminals of the AND gates 41 and 42 . The output terminals of the AND gates 41 and 42 are connected to a two-bit up-down counter 43 . The Q1 output of the up-down counter 43 is connected to the input terminal of an inverter 44 and to an input terminal of an AND gate 45 . The Q2 output terminal of the up-down counter 43 is connected to an input terminal of an AND gate 45 and to an input terminal of an AND gate 46 . The connection point of the resistor R 2 and the switch SW 2 is connected to the remaining input terminals of the AND gates 45 and 46 . The Q1 and Q2 output signals of the up-down counter 43 are supplied to the CPU via bus lines. The output terminal of the AND gate 45 is connected to first input terminals of the AND gates 51 and 52 . The remaining input terminal of the AND gate 51 is connected to the output terminal of the inverter 17 . The remaining input terminal of the AND gate 52 is connected to the output terminal of the inverter 18 . The output terminals of the AND gates 51 and 52 are connected to a four-bit up-down counter 53 . The output terminal of the AND gate 46 is connected to first input terminals of the AND gates 61 and 62 . The remaining input terminal of the AND gate 61 is connected to the other input terminal of the AND gate 51 . The remaining input terminal of the AND gate 62 is connected to the other input terminals of the AND gate 52 . The output terminals of the AND gates 61 and 62 are connected to a four-bit up-down counter 63 . The AND gates 41, 42, 45 and 46 of the up-down counter 43 and the inverter 44 form the mode A counter 21 . The AND gates 51 and 52 and the up-down counter 53 form the TV counter 25 . The AND gates 61 and 62 and the up-down counter 63 form the AV counter 26 . The operation of the circuit of Fig. 3 will now be described. Figures 4A through 4D include tables that indicate the modes and data for the bits of the mode A counter, the TV counter, and the AV counter. The operation of the above circuit will be described in connection with FIGS. 4A to 4D. If the automatic / manual switch SW 1 is switched on in the circuit according to FIG. 2 (setting to the AUTO position) and the mode switch SW 2 is switched on, the chip selection signal CSA is raised to H. Under this condition, when the up switch SW 5 is turned on, both input signals of the AND gate 41 are high. The output signal of the AND gate 41 is raised high. Therefore, the count of the up-down counter 43 is increased by one. If the downward switch SW 6 is switched on on the other side , the output signal of the inverter 18 is raised to H Both inputs of the AND gate 42 are held high, and as a result, the output of the AND gate 42 is raised to high. Therefore, the count is decreased by one.

By actuating the warm-up switch, the Q1 and Q2 outputs of the two-bit up-down counter 43 are both set to H. In this case, the mode switch SW 3 is kept turned on and the input signal lines to the AND gates 45 and 46 are at L. Therefore, the chip select signals CSEE and CSES are at L. When the mode switch SW 2 is turned off under this condition, they are all Inputs of the AND gate 45 to H. The chip selection signal CSEE is thus raised to H. On the other hand, when the output of inverter 44 is low, the output chip select signal CSES of AND gate 46 remains low. Since chip select signal CSEE has been raised to high (ie, the first input signals of AND gates 51 and 52 are high) ), the AND gates 51 and 52 can receive the up signal and the down signal, respectively. That is, when the mode switch SW 2 is turned on and the up switch SW 5 and the down switch SW 6 are turned on, the up-down counter 43 in the mode A counter 21 is operated. Then, when the mode switch SW 2 is turned off, the chip select signal CSA is set to L. Therefore, the up-down counter 43 is not operated. Only the down-down counter 53 in the TV counter 25 is operated. The output value Q4, Q3, Q2, Q1 of the up-down counter 53 and the corresponding shutter value are shown in Fig. 4B. When the mode switch SW 2 and the up-switch SW 5 or the down switch SW 6 are operated, the Q1 and Q2 output of the up-down counter 43 are set to "0" and "1". In this case, the output of the mode switch SW 2 is also at L. Therefore, the chip select signals CSEE and CSES remain at L. When the mode switch SW 2 is turned off under this condition, the signal line is kept at H, as a result of which the display unit 34 here switched on and thus show "2000" which value corresponds to the shutter speed of 1/2000 s. In the same way, the shutter speeds from 1/2000 s to 15 s can be displayed.

If the lens hood ring is in the automatic position A, the flash lamp mode, electron flash synchronization mode of the ma exposure mode cannot be selected. If in contrast, the lens hood ring in the position for manual operation the program Automa tic exposure mode and exposure priority priority automatic exposure mode cannot be selected. Therefore may cause errors when adjusting the exposure mode can be prevented.

In accordance with the invention the mode will be setting operation performed by operating the mode switch and up switch and down switch and the film speed adjustment operation and the exposure factor setting operation are performed by Operate the film sensitivity switch and the Be glow factor switch achieved, together with the Up switch and the down switch. So you can all required camera input data, namely  the exposure time, the aperture value, film sensitivity and exposure factor Push button operations are set.

Therefore, if the lens aperture ring is in the automatic position A can only be the aperture priority automatic exposure mode, the exposure time priority automatic exposure mode or the program Automatic exposure mode can be selected.

When the lens hood ring is in the position for manual operation only the flash lamp mode, electron flash synchronization mode or the Aperture priority auto exposure mode selected during the automatic exposure mode dus and the exposure time priority automatic exposure mode can not be selected. Hence the appearance errors in setting the exposure mode different. Since the film speed adjustment operation by the exposure factor setting operation by push buttons actuation can be tedious scales operations prevented.

Claims (8)

1. Automatic exposure control device for a photographic camera with a mode setting device for setting different exposure control modes for the automatic exposure mode of the photographic camera as well as with a digital evaluation circuit having a digital counting device and with a lens aperture ring on the camera lens, which has an automatic position and manual -Positions, characterized ,

• - that the mode setting device for automatic operating modes has a mode A counter ( 21 ) and for manual operating modes a mode M counter ( 22 ),
• - That the mode A counter ( 21 ) and the mode M counter ( 22 ) can be switched on in preparation by an automatic / manual switch (SW 1 ),
• - That by means of an upward or downward pulse control of exposure factor counters ( 25, 26 ) serving up switch (SW 5 ) or down switch (SW 6 ) a mode selection signal (CSES; CSEE; CS) in mode A counter ( 21 ) or mode M counter ( 22 ) is generated, by means of which the associated exposure factor counter ( 25 or 26 ) is activated via corresponding control lines,
• - That a mode switch (SW 2 ) is provided, which together with the automatic / manual switch (SW 1 ) via AND logic elements ( 12, 14 ) with the mode A counter ( 21 ) and mode M counter ( 22 ) is connected such that the automatic / manual switch (SW 1 ) which can be actuated via a lens aperture ring ( 1 ) of the camera lens in the automatic position (A), the mode A counter ( 21 ) and in the manual position selects the mode M counter ( 22 ), and
• - That enables the input of the signals of the up switch (SW 5 ) and the down switch (SW 6 ) in the mode A counter ( 21 ) or mode M counter ( 22 ) through the mode switch (SW 2 ) becomes.

2. Automatic exposure control device according to claim 1, characterized in that both the mode A counter ( 21 ) and the mode M counter ( 22 ) provide an aperture priority automatic exposure mode. 3. Automatic exposure control device according to claim 1, characterized in that by the mode selection signal of the mode A counter ( 21 ) either a program automatic exposure mode, an aperture priority automatic exposure mode or an exposure time priority automatic exposure mode and by that Mode selection signal of the mode M counter ( 22 ), either a flash lamp mode, a manual exposure mode, an electron flash synchronization mode or an aperture priority automatic exposure mode is selected. 4. Automatic exposure control device according to claim 1, characterized in that an exposure time counter ( 25 ) and an aperture value counter ( 26 ) are provided with release inputs which are coupled to the mode A counter ( 21 ) via control lines (CSES, CSEE), wherein the aperture value counter ( 26 ) in the aperture priority automatic exposure mode and the exposure time counter ( 25 ) in the exposure time priority automatic exposure mode is selected and, when a signal is input from the up switch (SW 5 ) or down switch (SW 6 ), an output signal of the aperture value counter ( 26 ) or the exposure time counter ( 25 ) is changed to form the aperture value or exposure time value. 5. Automatic exposure control apparatus according to claim 1, characterized in that the exposure time counter (25) with the Mode-M counter is coupled (22), wherein the exposure time counter (25) in a manual exposure mode by a mode-M counter signal ( CS) is selected, and that upon input of a signal from the up switch (SW 5 ) or down switch (SW 6 ), the count content of the exposure time counter ( 25 ) is changed for the exposure time formation. 6. Automatic exposure control device according to claim 1, characterized in that a film speed setting switch (SW 3 ) for setting the film speed and a film speed counter ( 23 ) are provided, which is activated when the film speed setting switch (SW 3 ) is activated and that the counting content of the film speed counter ( 23 ) can be changed by actuating the up switch (SW 5 ) or down switch (SW 6 ). 7. Automatic exposure control device according to claim 1, characterized in that an exposure factor setting switch (SW 4 ) and an exposure factor counter ( 24 ) are provided, which is activated when the exposure factor setting switch (SW 4 ) is activated and that the counting content of the exposure factor counter ( 24 ) by actuating the Up switch (SW 5 ) or down switch (SW 6 ) can be changed. 8. Automatic exposure control device according to one of the preceding claims, characterized in that also a device ( 34 ) for displaying the exposure time, the aperture value, the film sensitivity and the exposure factor in accordance with the count content of the exposure time counter ( 25 ), the aperture value counter ( 26 ), the Film sensitivity counter ( 23 ) and the exposure factor counter ( 24 ) is provided.